about
Droplet-interface-bilayer assays in microfluidic passive networks.Developmental regulation of tau splicing is disrupted in stem cell-derived neurons from frontotemporal dementia patients with the 10 + 16 splice-site mutation in MAPTMiniaturised technologies for the development of artificial lipid bilayer systems.Emulsion technologies for multicellular tumour spheroid radiation assays.Intracellular protein determination using droplet-based immunoassays.Microfluidic single-cell array cytometry for the analysis of tumor apoptosis.Neuronal networks provide rapid neuroprotection against spreading toxicityControlled delivery of proteins into bilayer lipid membranes on chip.Binding of anionic lipids to at least three nonannular sites on the potassium channel KcsA is required for channel opening.A Microfluidic Platform for the Characterisation of CNS Active Compounds.Universal surface-enhanced Raman tags: individual nanorods for measurements from the visible to the infrared (514-1064 nm).On-chip electrocoalescence of microdroplets as a function of voltage, frequency and droplet size.Microfluidic array platform for simultaneous lipid bilayer membrane formation.Chemically induced synaptic activity between mixed primary hippocampal co-cultures in a microfluidic system.Formation of artificial lipid bilayers using droplet dielectrophoresis.Air-exposure technique for the formation of artificial lipid bilayers in microsystems.Controlled delivery of membrane proteins to artificial lipid bilayers by nystatin-ergosterol modulated vesicle fusion.Transitioning from multi-phase to single-phase microfluidics for long-term culture and treatment of multicellular spheroids.Real-time assessment of nanoparticle-mediated antigen delivery and cell response.A microdroplet-based shift register.Electrocoalescence mechanisms of microdroplets using localized electric fields in microfluidic channels.Electrically initiated upstream coalescence cascade of droplets in a microfluidic flow.Bilayer lipid membranes from falling droplets.Hysteresis in multiphase microfluidics at a T-junction.Toll-like receptor 3 activation impairs excitability and synaptic activity via TRIF signalling in immature rat and human neurons.Surface-Enhanced Raman Scattering Based Microfluidics for Single-Cell AnalysisDrug screening of biopsy-derived spheroids using a self-generated microfluidic concentration gradientMicromachined glass apertures for artificial lipid bilayer formation in a microfluidic systemModular Redox-Active Inorganic Chemical Cells: iCHELLsAbstract 5024: Drug screening of biopsy-derived multicellular spheroids using microfluidic technologyModeling and Characterization of an Electrowetting-Based Single-Mode Fiber Variable Optical AttenuatorTheoretical and experimental analysis of side-polished fiber optofluidic variable attenuatorIn-line single-mode fiber variable optical attenuator based on electrically addressable microdropletsBiocatalytic Self-Assembly of Nanostructured Peptide Microparticles using Droplet MicrofluidicsDesign and characterization of polymeric pressure sensors for wireless wind sail monitoringExperiments on aircraft flight parameter detection by on-skin sensorsApplicability of Field Programmable Analog Arrays to Capacitive Sensing in the Sub-pF RangeA non-invasive capacitive sensor strip for aerodynamic pressure measurement
P50
Q30643096-786923CC-02AD-4B4F-A3B8-F1DD614C40EEQ35999257-89F56D50-EC0D-4D22-AD29-3AC6F4C6BC23Q37981028-A408D7CF-CF66-4486-A7D8-9151C1B93FC4Q38828865-BE8B479F-B5EE-4BB6-863C-85A408946C50Q39541956-1C11F5E6-C4DE-4B93-90D3-8709D980CD2BQ39839969-A5F22840-F1A1-4AD4-B27D-D8FABFC2F5CDQ41139792-0C204933-299E-4CBF-A188-B05A6CD129ADQ41979043-AC984C69-2F3A-40A9-994E-EF94E10A461FQ42637385-ECED18C7-5DA9-4CE7-B923-63F1FDAC8261Q44462403-63F4A348-4619-4C61-B0E3-A3DF2F22E3D3Q46854847-7B9087E2-A7F2-469B-AC60-E1A4AACD30C1Q47174781-DF61E320-B77B-4842-94E5-9C8B8DE13AE6Q47372507-1B730929-807A-413E-ACA1-733E85412A1AQ48793868-43372C06-3F2D-4C50-B08D-8AFCC558E5F6Q50620066-BE08E6E7-A28A-41D4-B807-74BEFFE705BEQ50972860-4D4C6321-6D5B-4E82-959B-C520B6B53CA8Q51212029-E87ACC39-16B8-48E9-BCD4-299EF292B6C7Q51222644-5BBFBF88-6BA2-415A-BC99-75F9CAD41D73Q51232599-AB5BD66C-FF28-4E56-856B-A309C92C1726Q51554767-26B6B83C-EEBD-4FC8-AEEF-2C9871EE6CC6Q51555358-19074CEE-8901-46BD-A2C5-0D0EB2F0684AQ51562541-A8CC97D5-7C19-4E31-ACE6-914C7A858479Q51568908-7E69917B-8B11-4192-BF27-AF9CC8A10F18Q51612665-590EA12D-D11E-4C58-A0A7-C44F11ABF151Q51744322-56B4DDC3-7DBD-40CA-9A55-45E27EDF644EQ56978087-548664BD-B332-4235-B60E-FC5C3016F67BQ57050418-DAD17F35-B855-4FE9-A12E-E4319A5E4196Q57053807-0FECCD98-D30E-4D73-868B-F05EB466CD3EQ57383210-C549BADC-F55A-4E07-BCF5-63FFF2042A4DQ58222524-C06F5FA4-F021-4B26-BF4E-BCA86DDF3CCFQ58222529-BFF4C6A5-5AC6-4FA5-8BD7-8F07336AE3C5Q58222530-C19A9AAB-DB3A-4800-A0C7-BA55853AA9A7Q58222532-A978ED28-3A18-41D0-9DAC-8A7F115DCA39Q58222533-9F19ED23-341A-4EE8-9BE3-1C15B6D23C2DQ58222535-3B6EF377-78A4-4920-B131-8D801CE32C5EQ58222538-60C9D19F-7961-46F4-8BB6-BF55444FA834Q58222539-B0A19D5C-F42E-451F-B1B3-EE8F794F1287Q58222542-6F5B86B4-2C55-45AC-8F05-B314CC168FCA
P50
description
researcher
@en
wetenschapper
@nl
հետազոտող
@hy
name
Michele Zagnoni
@ast
Michele Zagnoni
@en
Michele Zagnoni
@es
Michele Zagnoni
@nl
Michele Zagnoni
@sl
type
label
Michele Zagnoni
@ast
Michele Zagnoni
@en
Michele Zagnoni
@es
Michele Zagnoni
@nl
Michele Zagnoni
@sl
prefLabel
Michele Zagnoni
@ast
Michele Zagnoni
@en
Michele Zagnoni
@es
Michele Zagnoni
@nl
Michele Zagnoni
@sl
P106
P1153
57189577103
P21
P31
P496
0000-0003-3198-9491